Wearable Sensing

✨ New here? Welcome to the #neurotech community! 👋 Meet our DSI technology — the industry-leading dry EEG system, designed to deliver exceptional signal quality and comfort. We’re revolutionizing wearable devices to take brain imaging into everyday real-world applications 🧠

Help shape the future of EEG accessibility! Take this 2-3 minute survey by QUASAR to share your insights on overcoming challenges with diverse hair types, and contribute to developing more inclusive EEG technologies!

🌟 Happy New Year from Wearable Sensing 🌟 As we welcome a new year, we’re proud to reflect on our growth and the milestones we achieved in 2024, thanks to our customers, partners, and the neuroscience community. 📦 Expanding our Reach In 2024, hundreds of our industry-leading DSI systems found new homes in research labs, neurotherapy centers, and industry settings worldwide, supporting new applications and driving the commercial neurotech revolution. 📚 Scientific Publications Our systems were featured in over 50 publications, articles and books, fueling innovation in neuroscience, cognitive psychology, virtual reality and beyond. 🌍 Conferences and Events This year we participated in 10+ conferences and events, showcasing new technology, sharing knowledge and taking part in the growth of brain-related developments. 👩💻 New Team Members We welcomed 5+ talented new team members and interns, strengthening our expertise in regulatory affairs, engineering, research, and customer support. As we look ahead to 2025, we’re excited to: ➡️ Continue our contributions to groundbreaking research ➡️ Support our growing community of users ➡️ Innovate new solutions for broader applications A heartfelt thank you to our customers, partners, and the entire neuroscience community for enabling and inspiring us to push the boundaries of what’s possible. #Neurotech #RevolutionizingEEG #2024Recap #NewYear

I had an incredible time last week introducing Villa College to the exciting capabilities and research applications of their new DSI system from Wearable Sensing! Huge thank you to Aishath Nasheeda for welcoming me to the Maldives and for bringing everyone together for the training. I look forward to seeing all the great work this talented group of researchers have planned, from fundamental neuroscience to mental health, clinical research, education and beyond 🧠

How do our brains respond to music? 🧠 🎻 🎷 EEG Hyperscanning is a neuroscience research technique that involves simultaneously recording the brain activity of multiple people in real-time, and synchronizing the activity during a task, such as performing music. By aligning the data, researchers can identify collective responses to specific elements like rhythm, tempo changes, or harmonies, uncovering insights into how we perceive music. This technique can also be used to better understand how music can alleviate the symptoms of cognitive disorders, like ADHD or Tourette's, or even how audiences’ brains respond collectively to a song, elucidating the social connections many of us experience through music. The advancement of high-quality dry EEG systems enables exciting new developments in these research areas, where collecting data in naturalistic, real-world environments is key to fundamentally understanding the underlying mechanisms in the brain. Check out this beautiful duet of Violin and Saxophone from our very own team members, Savanna and Iisak, wearing the industry-leading DSI-24. #EEG #Hyperscanning #Music #Duet #Neuroscience #Neurotech #Research  

Can 1 millisecond make all the difference in understanding the brain? 🧠 ⏱ In neuroscience research, timing is everything. To best understand how the brain processes information, we need precise synchronization of data from multiple sources—like EEG, behavioral tracking, and visual stimuli. A misalignment of even a millisecond can skew interpretations of things like cognitive responses, motor coordination, or real-time neurofeedback. In the video below, we are presenting a recognizable visual stimulus, Mickey Mouse, and looking at the cognitive response it evokes. This cognitive response is typically called an Event Related Potential, or ERP. Using Wearable Sensing's 'wireless trigger hub' device, we can mark the data at the exact instance the image was presented, and analyze the following activity in the brain, therefore allowing us to provide more accurate context to the response we observe. #Neuroscience #EEG #ERP #Neurotech #MickeyMouse 🐭

How many EEG channels do you need to localize sources in the brain? 🧠 Source localization is the process of identifying which regions in the brain are the origin of electrical activity observed on the scalp. In EEG research, this method is an important tool for understanding spatial position of brain activity in response to specific stimuli, such as an auditory tone or image. In general, the more electrodes (or channels) you use, the more detailed the mapping can be, which is why many researchers prefer to work with 64 or more channels for higher accuracy and resolution. However, it’s not always necessary to use that many channels. With modern EEG systems and advanced processing software like BESA GmbH, reliable source localization can still be achieved with fewer channels. For example, using the DSI-24, a 19-channel dry EEG system, we were able to capture an auditory evoked potential and generate a clean source localization plot. Of course, more channels will generally provide better spatial resolution, but this demonstrates that even with 19 channels, high-quality source localization is possible. Check out the plot below for an example of how the DSI-24 performed! #EEG #SourceLocalization #neuroscience #dryEEG #neurotech

#SfN2024 is a wrap! This year we shared a new booth design, our mind-controlled VR game (powered by #PhysioLabXR), and made many new connections with fellow neuroscientists and neurotech enthusiasts 🧠 Thanks to everyone who came by to chat with us and try on the industry-leading dry EEG system! Looking forward to next year in San Diego 🙌 Society for Neuroscience

This morning at #SfN24, Disha Gupta and her team from National Center for Adaptive Neurotechnologies (NCAN) is presenting their work examining the relationship between cortical mechanoreceptive processing and finger proprioception after chronic stroke 🧠, as well as its ability to predict improvements in finger proprioception following robot-based hand therapy 🦾 Drop by their poster # LBA25 or use the link below to learn more about this cutting edge research. https://lnkd.in/gXBFZ-58

How strong is your 🧠 activity? Stop by the Wearable Sensing booth # 739 at #SfN24 today to try the alpha brain challenge! Powered by #PhysioLabXR ✨